Abstract: A telecommunications module includes a main housing portion and a cover, the main housing portion defining a first sidewall, a front wall, a rear wall, a top wall, and a bottom wall, the cover defining a second sidewall when mounted on the main housing portion. An optical component located within the module receives an input signal from a signal input location of the housing and outputs an output signal toward a signal output location on the front wall. The telecommunications module is configured such that the signal input location can be selected to be either on the front wall or the rear wall of the main housing. The cover defines a protrusion extending from the second sidewall toward the main housing portion, the protrusion being selectively breakable to expose a recess on the front wall of the main housing portion that defines a signal input location.

Abstract: A rack includes a first termination block disposed at the first side of the rack. The termination block houses a termination arrangement including a plurality of sliding adapter modules. The adapter modules are configured to slide between a non-extended position and an extended position. The adapter modules move away from the rack when slid to the extended position. The adapter modules have first ports facing towards the top of the rack and second ports facing towards the bottom of the rack. Certain types of racks also have a cable storage arrangement disposed at the front of the rack.

Abstract: A fiber distribution device includes a swing frame chassis pivotally mounted to a support structure. At least a first optical splitter module is mounted to the swing frame chassis. Pigtails having connectorized ends are carried by the swing frame chassis and have portions that are routed generally vertically on the swing frame chassis. An optical termination field includes fiber optic adapters carried by the swing frame chassis. The fiber optic adapters are configured to receive the connectorized ends of the pigtails.

Abstract: A bend radius limiter adapted for installation on a fiber guide is disclosed. In one aspect, the bend radius limiter has a main body with a generally rounded outer surface and an interior surface that defines an interior volume. The main body is also configured with a first slot opening in the generally rounded outer surface that may optionally function as a first or second connecting feature. The bend radius limiter can also include a first connecting feature configured to retain the bend radius limiter onto the fiber guide. In one embodiment, the first connecting feature is located within the interior volume and is radially aligned with the first slot opening.

Abstract: A fiber optic connector assembly includes a connector and a carrier. The connector has first and second ends and a terminated fiber. The fiber defines a first end adjacent the first end of the connector and a second end protruding out of the second end of the connector. A carrier having a connector end and an opposite cable end is engaged with the connector. An alignment structure on the carrier includes a first end, a second end and a throughhole and also a cutaway extending perpendicularly to and communicating with the throughhole. The fiber is positioned within at least a portion of the throughhole with the second end located within the cutaway. A window is within the cutaway over the second end of the fiber for visually inspecting the alignment of the second end of the fiber with an end of another fiber.

Abstract: A tool is disclosed. The tool is for inserting a ferrule alignment sleeve within a sleeve mount of a fiber optic adapter, wherein the sleeve mount defines an axial bore and radially inwardly extending fingers for retaining the ferrule alignment sleeve therewithin. The tool includes a handle and a pin extending from the handle, the pin configured to slidably receive the ferrule alignment sleeve, the pin defining longitudinal keys for mating with gaps defined between the radially inwardly extending fingers of the sleeve mount, wherein the tool can be used as a ferrule alignment sleeve insertion tool if the pin is inserted into the axial bore in a first orientation and is configured to be used as a ferrule alignment sleeve removal tool if the pin is inserted into the axial bore in a second orientation from an opposite end of the axial bore.

Abstract: A packaging arrangement for telecommunications cabling is disclosed herein. The packaging arrangement includes a modular spool assembly defined by a first flange, an opposing second flange, and a spool hub separating the first flange from the second flange, wherein a telecommunications cable may be wound between the first and second flanges. Each flange defines a first cable contact side, a second cable-end storage side, and an opening allowing the telecommunications cable to pass from the first side to the second side, the second side defining a storage compartment for storing an end of the telecommunications cable passing through the opening in the flange.

Abstract: A distributed base station radio system includes first channelized to broadband conversion unit that receives first downlink channelized data for first radio frequency band from first channelized radio frequency source; and first universal remote radio head communicatively coupled to first channelized to broadband conversion unit. First channelized to broadband conversion unit converts first downlink channelized data into a first downlink broadband signal. First channelized to broadband conversion unit communicates the first downlink broadband signal to first universal remote radio head. First universal remote radio head receives first downlink broadband signal. First universal remote radio head frequency converts the first downlink broadband signal into first downlink radio frequency signals in first radio frequency band. First universal remote radio head is further configured to transmit first downlink radio frequency signals in first radio frequency band to first subscriber unit.

Abstract: A fiber optic telecommunications device includes a rack for mounting a plurality of chassis, each chassis including a plurality of trays slidably mounted thereon and arranged in a vertically stacked arrangement.

Abstract: A payout spool for a cable includes a base, a spool, and a disconnect/reconnect device. The cable extends between a first and a second end. The payout spool pays out the cable when the first end of the cable is pulled away from the payout spool. The base includes a terminal for transmitting and/or receiving a signal to and/or from the cable. The spool is rotatably mounted to the base about an axis. The spool is adapted to unwrap the cable about a wrapping area of the spool when the spool is rotated about the axis. The disconnect/reconnect device may be adapted to disconnect the second end of the cable from the terminal when the payout spool pays out the cable and reconnect the same when the payout spool is not paying out the cable.

Abstract: A cable storage system includes a box and at least one cable retainer. The box includes a plurality of walls at least partially defining a box interior. The box receives a cable from an exterior of the box. At least one wall of the box defines a retainer opening. The retainer is adapted to receive an unsecured length of the cable and may be selectively secured to the retainer opening. When the retainer is secured to the retainer opening, the retainer extends out of the interior of the box. Multiple retainers may be used to store additional lengths of cable.

Abstract: A fiber optic connector holder is sized to fit within an opening for mounting a fiber optic adapter. The fiber optic connector holder is configured to permit a fiber optic connector with a dust cap positioned about a ferrule and a polished end face of an optical fiber held by the ferrule to be inserted within and releasably held by the connector holder. A system for holding fiber optic connectors includes a fiber optic connector holder mounted within an opening in a bulkhead for mounting a fiber optic adapter. The fiber optic connector holder is configured to receive a fiber optic connector with a dust cap mounted about a ferrule and polished end face of an optical fiber held by the ferrule. An optical fiber connector may be held to a bulkhead when the fiber optic connector includes a dust cap mounted about a ferrule and a polished end face of an optical fiber held by the ferrule.

Abstract: A cable pass-thru assembly includes a fiber optic cable and a cable pass-thru fitting. The fiber optic cable includes an optical fiber and a strength member. The cable pass-thru fitting is adapted to receive at least a portion of the fiber optic cable. The cable pass-thru fitting includes a fitting assembly having a body defining a thru-bore that extends through the body. The thru-bore includes a tapered portion. The cable pass-thru fitting further includes a cable retention member adapted for engagement with the tapered portion of the body. The cable retention member defines a plurality of through which the strength member of the fiber optic cable is routed. The plurality of grooves is adapted to secure the strength member when the cable retention member is inserted into the thru-bore.

Abstract: A telecommunications module includes an optical wavelength division multiplexer/demultiplexer configured to demultiplex a first optical signal input into the telecommunications module into a plurality of different wavelengths, a fiber optic splitter configured to split a second optical signal input into the telecommunication module into a plurality of optical signals, and a plurality of optical add/drop filters, each of the optical add/drop filters configured to combine one of the optical signals that has been split by the fiber optic splitter and one of the wavelengths that has been demultiplexed by the optical wavelength division multiplexer/demultiplexer into a combination output signal that is output from the telecommunications module.

Abstract: A distributed antenna system comprises a plurality of antennas and a multi-port hub. The multi-port hub comprises an interface to a telecommunications network and a plurality of transceivers. The multi-port hub is configured to operate in a first mode (“normal” mode) in which the multi-port hub receives a downlink communications signal via the interface and distributes the downlink communications signal to the plurality of antennas using a selected downlink transmission frequency within a downlink frequency range and in which the multi-port hub receives uplink communications signals from the plurality of antennas at a selected uplink receive frequency. The multi-port hub is also configured to operate in a second mode (“listening” mode) in which the multi-port hub receives communications signals from the plurality of antennas at one or more frequencies within the downlink frequency range.

Abstract: A fiber optic and electrical connection system includes a fiber optic cable, a ruggedized fiber optic connector, a ruggedized fiber optic adapter, and a fiber optic enclosure. The cable includes one or more electrically conducting strength members. The connector, the adapter, and the enclosure each have one or more electrical conductors. The cable is terminated by the connector with the conductors of the connector in electrical communication with the strength members. The conductors of the connector electrically contact the conductors of the adapter when the connector and the adapter are mechanically connected. And, the conductors of the adapter electrically contact the conductors of the enclosure when the adapter is mounted on the enclosure.

Abstract: Couplers for a cable trough system including a terminal end sized to receive a terminal end of a trough member along a longitudinal direction of the body. A spring may be coupled to the body for securing the terminal end of the trough member to the coupler, the spring including first and second spring arms extending generally in opposition to one another in a plane generally parallel to the longitudinal direction. The spring may be received in a slot formed by the trough member. Also included may be a spring release mechanism coupled to the body, the spring release mechanism sliding in the longitudinal direction between a locked position, such that the first and second spring arms engage the terminal end of the trough, and an unlocked position, such that the first and second fingers release the first and second arms of the spring.

Abstract: A rack system includes one or more racks each configured to receive at least one distribution module. Each rack includes management sections located at the front of the rack; troughs located at the rear of the rack; horizontal channels extending between the management sections and the trough; a storage area located at a first of opposing sides of the rack; a front vertical channel that connects to the storage area and at least some of the management sections; and a travel channel at the rear of the first rack that connects the storage area to the troughs.

Abstract: A fiber optic enclosure assembly includes a fiber optic enclosure and a cable shroud assembly. The fiber optic enclosure includes a base having a first end, an oppositely disposed second end, and first and second sides that extend between the first and second ends. A cover is engaged to the base. The cable shroud assembly includes a first piece engaged to the first and second sides of the base of the fiber optic enclosure at the first end of the base. The first piece includes a base wall, a first side wall that extends outwardly from the base wall and an oppositely disposed second side wall. The first piece includes a plurality of cable management spools disposed on the base wall. A second piece is engaged to the first piece. The second piece is configured to cover cables that enter/exit the first end of the base.

Abstract: An integration panel comprises a control module, a plurality of radio frequency (RF) modules, and a backplane configured to couple the plurality of RF modules to the control module. Each of the plurality of RF modules is configured to be coupled to a respective network device and to a host unit of a distributed antenna system. Each RF module is further configured to condition the RF signals received from the respective network device and to provide the conditioned RF signals to the host unit. Each of the RF modules is configured to sample the conditioned RF signals and to provide the sampled RF signals to the control module via the backplane. The control module is configured to perform signal analysis of the sampled RF signals and to provide the results of the signal analysis to a user device located remotely from the integration panel.